Thermoacoustic refrigeration occurs in periodic flow in a duct with he
at transfer within the fluid and to the tube. This study considers the
periodic limit cycle with large pressure oscillations that is obtaine
d in a tube when prescribed, phase-shifted, periodic velocities at the
tube ends, at frequencies lower than acoustic eigenmodes, sweep a len
gth comparable to the tube length. The temperature differences between
the two ends are of arbitrary magnitude, heat transfer in the transve
rse direction within the fluid is assumed to be very effective and the
thermal mass of the wall is large. The geometry is two-dimensional, a
xisymmetric, and conduction is accounted for, not only in the fluid, b
ut also with and within the tube wall. A perturbation solution valid i
n a local near-isothermal limit determines the equilibrium longitudina
l temperature profile that is reached at the periodic regime, the pres
sure field including longitudinal gradients, and the longitudinal enth
alpy flux. Results are presented for tubes open at both ends and also
with one end closed. In the latter case, a singularity occurs in the t
emperature at the closed end, with behaviour identical to Rott's resul
t for acoustic flow with small pressure amplitude. Other new results o
btained for tubes open at both ends show that when velocities at both
ends are in opposite phase, internal singularities in the temperature
profiles may occur.